An array is an extremely simple data structure. In memory, it is a simple contiguous block. Say each item in the array is four bytes, and the array has room for 100 elements. Then the array is simply 400 contiguous bytes in memory, and your variable assigned to the array is a pointer to the first element. Say this is at location 10000 in memory.
When you access element #3 of the array, like this:
myarray = 17;
...what happens is very simple: 3 multiplied by the element size (4 bytes) is added to the base pointer. In this example it's 10000 + 3 * 4 = 10012. Then you simply write to the 4 bytes located at address 10012. Trivially simple math.
A hashtable is not an elementary data structure. It could be implemented in various ways, but a simple one might be an array of 256 lists. Then when you access the hashtable, first you have to calculate the hash of your key, then look up the right list in the array, and finally walk along the list to find the right element. This is a much more complicated process.
A simple array is always going to be faster than a hashtable. What the text you cite is getting at is that if the data is very sparse... you might need a very large array to do this simple calculation. In that case you could use a lot less memory space to hold the hash table.
Consider if your characters were Unicode -- two bytes each. That's 65536 possible characters. And say you're only talking about strings with 256 or fewer characters. To count those characters with an array, you would need to make an array with 64K elements, one byte each... taking 64K of memory. The hashtable on the other hand, implemented like I mentioned above, might take only 4*64 bytes for the array of list pointers, and then 5-8 bytes per list element. So if you were processing a 256-character string with say 64 unique Unicode characters used, it would take up a total of at most 768 bytes. Under these conditions, the hashtable would be using much less memory. But it's always going to be slower.
Finally, in the simple case you show, you're probably just talking about the Latin alphabet, so if you force lowercase, you could have an array with just 26 elements, and make them as large as you want so you could count as many characters as you'll need. Even if it's 4 billion, you would need just 26 * 4 = 104 character array. So that's definitely the way to go here.